Difference between revisions of "Part:BBa K3431001"
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This toehold switch has been designed to open up its hairpin loop structure upon binding with miRNA-21, resulting in the translation of downstream reporter protein. The design of toehold switch can be separated into the following 5 regions from its 5' end: trigger binding sites, stem region, loop region with RBS, complimentary stem region with start codon, and linker amino acids. In our constructions of toehold switches for miRNA-21, we optimised the region of loop with RBS and linker amino acids based on three articles: the original work on toehold switch (Green, A.A. et al., 2014), the adaptation of toehold switch to detect zika virus (Pardee, K. et al., 2016), and novel toehold switch design for detection of miRNA in mammalian cells (Wang, S. et al., 2019) . We chose to test the 3 different loop structures and 2 different linker structures (Pardee, K. et al. and Wang, S. et al.) from the above-mentioned studies. | This toehold switch has been designed to open up its hairpin loop structure upon binding with miRNA-21, resulting in the translation of downstream reporter protein. The design of toehold switch can be separated into the following 5 regions from its 5' end: trigger binding sites, stem region, loop region with RBS, complimentary stem region with start codon, and linker amino acids. In our constructions of toehold switches for miRNA-21, we optimised the region of loop with RBS and linker amino acids based on three articles: the original work on toehold switch (Green, A.A. et al., 2014), the adaptation of toehold switch to detect zika virus (Pardee, K. et al., 2016), and novel toehold switch design for detection of miRNA in mammalian cells (Wang, S. et al., 2019) . We chose to test the 3 different loop structures and 2 different linker structures (Pardee, K. et al. and Wang, S. et al.) from the above-mentioned studies. | ||
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For this particular toehold switch (pp21), We incorporate the loop and linker sequence from work of Wang, S. et al. to test out whether optimisations specific to mammalian cells can have a better regulatory function for downstream protein expression in PURExpress in vitro protein synthesis system, on which our project of diagnosing oral cancer with toehold switch and glucose meter are based. | For this particular toehold switch (pp21), We incorporate the loop and linker sequence from work of Wang, S. et al. to test out whether optimisations specific to mammalian cells can have a better regulatory function for downstream protein expression in PURExpress in vitro protein synthesis system, on which our project of diagnosing oral cancer with toehold switch and glucose meter are based. | ||
Revision as of 07:44, 18 October 2020
pp21_B Toehold Switch for miR-21 Detection
This toehold switch has been designed to open up its hairpin loop structure upon binding with miRNA-21, resulting in the translation of downstream reporter protein. The design of toehold switch can be separated into the following 5 regions from its 5' end: trigger binding sites, stem region, loop region with RBS, complimentary stem region with start codon, and linker amino acids. In our constructions of toehold switches for miRNA-21, we optimised the region of loop with RBS and linker amino acids based on three articles: the original work on toehold switch (Green, A.A. et al., 2014), the adaptation of toehold switch to detect zika virus (Pardee, K. et al., 2016), and novel toehold switch design for detection of miRNA in mammalian cells (Wang, S. et al., 2019) . We chose to test the 3 different loop structures and 2 different linker structures (Pardee, K. et al. and Wang, S. et al.) from the above-mentioned studies.
For this particular toehold switch (pp21), We incorporate the loop and linker sequence from work of Wang, S. et al. to test out whether optimisations specific to mammalian cells can have a better regulatory function for downstream protein expression in PURExpress in vitro protein synthesis system, on which our project of diagnosing oral cancer with toehold switch and glucose meter are based.
References:
Green, A. A., Silver, P. A., Collins, J. J., & Yin, P. (2014). Toehold switches: de-novo-designed regulators of gene expression. Cell, 159(4), 925-939.
Pardee, K., Green, A. A., Takahashi, M. K., Braff, D., Lambert, G., Lee, J. W., ... & Daringer, N. M. (2016). Rapid, low-cost detection of Zika virus using programmable biomolecular components. Cell, 165(5), 1255-1266.
Wang, S., Emery, N. J., & Liu, A. P. (2019). A novel synthetic toehold switch for microRNA detection in mammalian cells. ACS synthetic biology, 8(5), 1079-1088.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]